---
title: 'Bazel Tutorial: Build a Go Project'
---



This tutorial introduces you to the basics of Bazel by showing you how to build
a Go (Golang) project. You'll learn how to set up your workspace, build a small
program, import a library, and run its test. Along the way, you'll learn key
Bazel concepts, such as targets and `BUILD` files.

Estimated completion time: 30 minutes

## Before you begin

### Install Bazel

Before you get started, first [install bazel](/install) if you haven't done so
already.

You can check if Bazel is installed by running `bazel version` in any directory.

### Install Go (optional)

You don't need to [install Go](https://go.dev/doc/install) to build Go projects
with Bazel. The Bazel Go rule set automatically downloads and uses a Go
toolchain instead of using the toolchain installed on your machine. This ensures
all developers on a project build with same version of Go.

However, you may still want to install a Go toolchain to run commands like `go
get` and `go mod tidy`.

You can check if Go is installed by running `go version` in any directory.

### Get the sample project

The Bazel examples are stored in a Git repository, so you'll need to [install
Git](https://git-scm.com/book/en/v2/Getting-Started-Installing-Git) if you
haven't already. To download the examples repository, run this command:

```posix-terminal
git clone https://github.com/bazelbuild/examples
```

The sample project for this tutorial is in the `examples/go-tutorial` directory.
See what it contains:

```none
go-tutorial/
└── stage1
└── stage2
└── stage3
```

There are three subdirectories (`stage1`, `stage2`, and `stage3`), each for a
different section of this tutorial. Each stage builds on the previous one.

## Build with Bazel

Start in the `stage1` directory, where we'll find a program. We can
build it with `bazel build`, then run it:

```posix-shell
$ cd go-tutorial/stage1/
$ bazel build //:hello
INFO: Analyzed target //:hello (0 packages loaded, 0 targets configured).
INFO: Found 1 target...
Target //:hello up-to-date:
  bazel-bin/hello_/hello
INFO: Elapsed time: 0.473s, Critical Path: 0.25s
INFO: 3 processes: 1 internal, 2 darwin-sandbox.
INFO: Build completed successfully, 3 total actions

$ bazel-bin/hello_/hello
Hello, Bazel! 💚
```

We can also build run the program with a single `bazel run` command:

```posix-shell
$ bazel run //:hello
bazel run //:hello
INFO: Analyzed target //:hello (0 packages loaded, 0 targets configured).
INFO: Found 1 target...
Target //:hello up-to-date:
  bazel-bin/hello_/hello
INFO: Elapsed time: 0.128s, Critical Path: 0.00s
INFO: 1 process: 1 internal.
INFO: Build completed successfully, 1 total action
INFO: Running command line: bazel-bin/hello_/hello
Hello, Bazel! 💚
```

### Understanding project structure

Take a look at the project we just built.

`hello.go` contains the Go source code for the program.

```go
package main

import "fmt"

func main() {
	fmt.Println("Hello, Bazel! 💚")
}
```

`BUILD` contains some instructions for Bazel, telling it what we want to build.
You'll typically write a file like this in each directory. For this project, we
have a single `go_binary` target that builds our program from `hello.go`.

```bazel
load("@rules_go//go:def.bzl", "go_binary")

go_binary(
    name = "hello",
    srcs = ["hello.go"],
)
```

`MODULE.bazel` tracks your project's dependencies. It also marks your project's
root directory, so you'll only write one `MODULE.bazel` file per project. It
serves a similar purpose to Go's `go.mod` file. You don't actually need a
`go.mod` file in a Bazel project, but it may still be useful to have one so that
you can continue using `go get` and `go mod tidy` for dependency management. The
Bazel Go rule set can import dependencies from `go.mod`, but we'll cover that in
another tutorial.

Our `MODULE.bazel` file contains a single dependency on
[rules_go](https://github.com/bazel-contrib/rules_go), the Go rule set. We need
this dependency because Bazel doesn't have built-in support for Go.

```bazel
bazel_dep(
    name = "rules_go",
    version = "0.50.1",
)
```

Finally, `MODULE.bazel.lock` is a file generated by Bazel that contains hashes
and other metadata about our dependencies. It includes implicit dependencies
added by Bazel itself, so it's quite long, and we won't show it here. Just like
`go.sum`, you should commit your `MODULE.bazel.lock` file to source control to
ensure everyone on your project gets the same version of each dependency. You
shouldn't need to edit `MODULE.bazel.lock` manually.

### Understand the BUILD file

Most of your interaction with Bazel will be through `BUILD` files (or
equivalently, `BUILD.bazel` files), so it's important to understand what they
do.

`BUILD` files are written in a scripting language called
[Starlark](https://bazel.build/rules/language), a limited subset of Python.

A `BUILD` file contains a list of
[targets](https://bazel.build/reference/glossary#target). A target is something
Bazel can build, like a binary, library, or test.

A target calls a rule function with a list of
[attributes](https://bazel.build/reference/glossary#attribute) to describe what
should be built. Our example has two attributes: `name` identifies the target on
the command line, and `srcs` is a list of source file paths (slash-separated,
relative to the directory containing the `BUILD` file).

A [rule](https://bazel.build/reference/glossary#rule) tells Bazel how to build a
target. In our example, we used the
[`go_binary`](https://github.com/bazel-contrib/rules_go/blob/master/docs/go/core/rules.md#go_binary)
rule. Each rule defines [actions](https://bazel.build/reference/glossary#action)
(commands) that generate a set of output files. For example, `go_binary` defines
Go compile and link actions that produce an executable output file.

Bazel has built-in rules for a few languages like Java and C++. You can find
their [documentation in the Build
Encyclopedia](https://bazel.build/reference/be/overview#rules). You can find
rule sets for many other languages and tools on the [Bazel Central Registry
(BCR)](https://registry.bazel.build/).

## Add a library

Move onto the `stage2` directory, where we'll build a new program that
prints your fortune. This program uses a separate Go package as a library that
selects a fortune from a predefined list of messages.

```none
go-tutorial/stage2
├── BUILD
├── MODULE.bazel
├── MODULE.bazel.lock
├── fortune
│   ├── BUILD
│   └── fortune.go
└── print_fortune.go
```

`fortune.go` is the source file for the library. The `fortune` library is a
separate Go package, so its source files are in a separate directory. Bazel
doesn't require you to keep Go packages in separate directories, but it's a
strong convention in the Go ecosystem, and following it will help you stay
compatible with other Go tools.

```go
package fortune

import "math/rand"

var fortunes = []string{
	"Your build will complete quickly.",
	"Your dependencies will be free of bugs.",
	"Your tests will pass.",
}

func Get() string {
	return fortunes[rand.Intn(len(fortunes))]
}
```

The `fortune` directory has its own `BUILD` file that tells Bazel how to build
this package. We use `go_library` here instead of `go_binary`.

We also need to set the `importpath` attribute to a string with which the
library can be imported into other Go source files. This name should be the
repository path (or module path) concatenated with the directory within the
repository.

Finally, we need to set the `visibility` attribute to `["//visibility:public"]`.
[`visibility`](https://bazel.build/concepts/visibility) may be set on any
target. It determines which Bazel packages may depend on this target. In our
case, we want any target to be able to depend on this library, so we use the
special value `//visibility:public`.

```bazel
load("@rules_go//go:def.bzl", "go_library")

go_library(
    name = "fortune",
    srcs = ["fortune.go"],
    importpath = "github.com/bazelbuild/examples/go-tutorial/stage2/fortune",
    visibility = ["//visibility:public"],
)
```

You can build this library with:

```posix-shell
$ bazel build //fortune
```

Next, see how `print_fortune.go` uses this package.

```go
package main

import (
	"fmt"

	"github.com/bazelbuild/examples/go-tutorial/stage2/fortune"
)

func main() {
	fmt.Println(fortune.Get())
}
```

`print_fortune.go` imports the package using the same string declared in the
`importpath` attribute of the `fortune` library.

We also need to declare this dependency to Bazel. Here's the `BUILD` file in the
`stage2` directory.

```bazel
load("@rules_go//go:def.bzl", "go_binary")

go_binary(
    name = "print_fortune",
    srcs = ["print_fortune.go"],
    deps = ["//fortune"],
)
```

You can run this with the command below.

```posix-shell
bazel run //:print_fortune
```

The `print_fortune` target has a `deps` attribute, a list of other targets that
it depends on. It contains `"//fortune"`, a label string referring to the target
in the `fortune` directory named `fortune`.

Bazel requires that all targets declare their dependencies explicitly with
attributes like `deps`. This may seem cumbersome since dependencies are *also*
specified in source files, but Bazel's explictness gives it an advantage. Bazel
builds an [action graph](https://bazel.build/reference/glossary#action-graph)
containing all commands, inputs, and outputs before running any commands,
without reading any source files. Bazel can then cache action results or send
actions for [remote execution](https://bazel.build/remote/rbe) without built-in
language-specific logic.

### Understanding labels

A [label](https://bazel.build/reference/glossary#label) is a string Bazel uses
to identify a target or a file. Labels are used in command line arguments and in
`BUILD` file attributes like `deps`. We've seen a few already, like `//fortune`,
`//:print-fortune`, and `@rules_go//go:def.bzl`.

A label has three parts: a repository name, a package name, and a target (or
file) name.

The repository name is written between `@` and `//` and is used to refer to a
target from a different Bazel module (for historical reasons, *module* and
*repository* are sometimes used synonymously). In the label,
`@rules_go//go:def.bzl`, the repository name is `rules_go`. The repository name
can be omitted when referring to targets in the same repository.

The package name is written between `//` and `:` and is used to refer to a
target in from a different Bazel package. In the label `@rules_go//go:def.bzl`,
the package name is `go`. A Bazel
[package](https://bazel.build/reference/glossary#package) is a set of files and
targets defined by a `BUILD` or `BUILD.bazel` file in its top-level directory.
Its package name is a slash-separated path from the module root directory
(containing `MODULE.bazel`) to the directory containing the `BUILD` file. A
package may include subdirectories, but only if they don't also contain `BUILD`
files defining their own packages.

Most Go projects have one `BUILD` file per directory and one Go package per
`BUILD` file. The package name in a label may be omitted when referring to
targets in the same directory.

The target name is written after `:` and refers to a target within a package.
The target name may be omitted if it's the same as the last component of the
package name (so `//a/b/c:c` is the same as `//a/b/c`; `//fortune:fortune` is
the same as `//fortune`).

On the command-line, you can use `...` as a wildcard to refer to all the targets
within a package. This is useful for building or testing all the targets in a
repository.

```posix-shell
# Build everything
$ bazel build //...
```

## Test your project

Next, move to the `stage3` directory, where we'll add a test.

```none
go-tutorial/stage3
├── BUILD
├── MODULE.bazel
├── MODULE.bazel.lock
├── fortune
│   ├── BUILD
│   ├── fortune.go
│   └── fortune_test.go
└── print-fortune.go
```

`fortune/fortune_test.go` is our new test source file.

```go
package fortune

import (
	"slices"
	"testing"
)

// TestGet checks that Get returns one of the strings from fortunes.
func TestGet(t *testing.T) {
	msg := Get()
	if i := slices.Index(fortunes, msg); i < 0 {
		t.Errorf("Get returned %q, not one the expected messages", msg)
	}
}
```

This file uses the unexported `fortunes` variable, so it needs to be compiled
into the same Go package as `fortune.go`. Look at the `BUILD` file to see
how that works:

```bazel
load("@rules_go//go:def.bzl", "go_library", "go_test")

go_library(
    name = "fortune",
    srcs = ["fortune.go"],
    importpath = "github.com/bazelbuild/examples/go-tutorial/stage3/fortune",
    visibility = ["//visibility:public"],
)

go_test(
    name = "fortune_test",
    srcs = ["fortune_test.go"],
    embed = [":fortune"],
)
```

We have a new `fortune_test` target that uses the `go_test` rule to compile and
link a test executable. `go_test` needs to compile `fortune.go` and
`fortune_test.go` together with the same command, so we use the `embed`
attribute here to incorporate the attributes of the `fortune` target into
`fortune_test`. `embed` is most commonly used with `go_test` and `go_binary`,
but it also works with `go_library`, which is sometimes useful for generated
code.

You may be wondering if the `embed` attribute is related to Go's
[`embed`](https://pkg.go.dev/embed) package, which is used to access data files
copied into an executable. This is an unfortunate name collision: rules_go's
`embed` attribute was introduced before Go's `embed` package. Instead, rules_go
uses the `embedsrcs` to list files that can be loaded with the `embed` package.

Try running our test with `bazel test`:

```posix-shell
$ bazel test //fortune:fortune_test
INFO: Analyzed target //fortune:fortune_test (0 packages loaded, 0 targets configured).
INFO: Found 1 test target...
Target //fortune:fortune_test up-to-date:
  bazel-bin/fortune/fortune_test_/fortune_test
INFO: Elapsed time: 0.168s, Critical Path: 0.00s
INFO: 1 process: 1 internal.
INFO: Build completed successfully, 1 total action
//fortune:fortune_test                                          PASSED in 0.3s

Executed 0 out of 1 test: 1 test passes.
There were tests whose specified size is too big. Use the --test_verbose_timeout_warnings command line option to see which ones these are.
```

You can use the `...` wildcard to run all tests. Bazel will also build targets
that aren't tests, so this can catch compile errors even in packages that don't
have tests.

```posix-shell
$ bazel test //...
```

## Conclusion and further reading

In this tutorial, we built and tested a small Go project with Bazel, and we
learned some core Bazel concepts along the way.

-   To get started building other applications with Bazel, see the tutorials for
    [C++](/start/cpp), [Java](/start/java), [Android](/start/android-app), and
    [iOS](/start/ios-app).
-   You can also check the list of [recommended rules](/rules) for other
    languages.
-   For more information on Go, see the
    [rules_go](https://github.com/bazel-contrib/rules_go) module, especially the
    [Core Go
    rules](https://github.com/bazel-contrib/rules_go/blob/master/docs/go/core/rules.md)
    documentation.
-   To learn more about working with Bazel modules outside your project, see
    [external dependencies](/docs/external). In particular, for information on
    how to depend on Go modules and toolchains through Bazel's module system,
    see [Go with
    bzlmod](https://github.com/bazel-contrib/rules_go/tree/master/docs/go/core/bzlmod.md).
